C-DIFF: Creating an Artificial Biome. Oral Syringe/multi pill blister packs.

Creating artificial Biome to help curtail virulent Cdiff expansion:

This could be made from large vat fermentation (if fermentation is even needed—it just makes it easier to absorb) of materials and made into pill/ oral syringe form.

Other than diarrhea dehydration combating waters with electrolytes.

will need probiotics from live yoghurt. Powdered calcium which can be made from almonds/flax/hemp or soy depending on nation/human type.

Some form of metamucile or powder ground oats, lentils, flaxseed(again glad is great) or some citrus’s.

Powdered egg/chicken or turkey.

The liquid base of the pill gel would be juiced vegetables cooked well. Beets, cucumbers, celery.

Dried powdered potatoes or bananas, white rice as a starch base.

Combining all of these in a powdered form and combining them with liquified vegetables in an oral syringe or multiple pill delivery system should slow or stop c-diff spread as outbreaks occur during upcoming heatwaves. Making the outer shells heat resistant will also be a factor. Not a doctor. Just trying to help.

Best of luck.


Creating non fissile materials that conduct electricity. Got it to roughly .5 kg at 32,356 kJ/kg. About 9 kWh. It’ll last about 10,000 years. It’ll decay to non radioactive materials wholly unless there’s bad atoms within the build.

Basic data.

Then you can recycle the crystals i designed in it by cutting them out, while the rest of the crystals have decayed into stable non reactive isotopes during the end of their life time, So unless the main handler atom becomes fissile by some other means and spontaneously fissions, which safeties can be set up for, this may be our safest bet so far.

We currently need 23 of the 201 x10^12 Terawatt-hours, so it’ll future proof the planet. ^13= 1813.2363 Terawatt-hours. Then we just add more in as needed. Plus due to its size every country can have one and we all plug in start working on the next issues like acid rains and what it’s going to do to our food supplies. They’re also not subnanometer in size as far as I can tell, though if I’m honest I was too tired to do the volume of the molecule.

Have a good night/day.


What to do next for myself I suppose. Finfet Improvement Designed. Sub Nano Semiconductors. Transistors. Capacitors.

I’m optimizing these sub nanometer semiconductors. I need to learn about quantum tunneling with real world data to see how it spreads through the materials. I understand how the wave function moves partially or wholly through the material if enough energy is put into it, and I’m hoping that by developing this novel production concept and new lithography set up that’s more stable and should eliminate the dreaded angled entry waste points. I also understand the wavelength that I want to use and it’s limitations and needs for what to expect to lose per build platter. It depends on the platter size of course but if I’m building 500 units across, which would be small, I could essentially lose roughly an electrons width across the platter. I call it a platter, though it wont in the technical sense.

It’s time that the tech had an upgrade. The problem is that I need to produce such a high number and get funding as well as get some traction behind me to allow for high voltage energy points. I’ve then got to work on batteries though honestly a hand crank squeezed once to produce an amplified fort nights worth of energy by chugging an alternator or two or even a stifling engine that runs off of body heat that I’ve got sitting here in my head. I know the materials I would use for it, but I doubt it would catch on, but here’s my thought process on what I’m looking to do:

I’ve designed a Finfet-style multigate transistor except it can run from any direction and do all of the functions possible from any of the other sides. It can also be redundancy proofed through a dual connection and it would still truly run any functions, even simultaneously if timed correctly.

Once I can get a server or more powerful hardware (fingers crossed to Wacom for their generosity) to build a full mole of the material or even a useful amount like what’s used in an Apple A12x chip 6.5 billion transistors. On top of that I’ve designed a capacitor that uses the semiconductors materials.

My advisor says I should patent it and then release it but I see these videos of what’s to come and the country’s where heat waves are wiping out thousands of lives, of the roughly 170,000 people dying per day and it gets to me. I know that my first patent, once in production if possible, and accepted by the community will be able to save millions of lives due to being able to go anywhere in the body. Solving the energy crisis with these designs may save future millions to billions (I know how absolutely insane that sounds and I take no ego in it). I know I want the energy spread out cheaply, and likely subsidized by their governments with my company getting a small trickle cut that would compound into a ridiculous amount if it becomes accepted. Then I can work on vertical farming, and a new toilet system for those that need it. I have so much to do.

I am a man of simple means at the moment. I live on disability and eat off of $15 per week in the U.S. which is not a lot. I’m currently sustaining myself with .38 cent burritos which I know are not good for me, but at least I’ve stopped gaining weight from my meds. I keep watching that clip of Seth Rogan as Woz, who says “It’s not binary—you can be decent and gifted.” I hope to live up to that, as I’ve not had much chance in life to do good work with what functions I do have. But I’m going to try, and I’ll keep at it until there is some positive result and someone else’s life is better. I know mine is basically over at this point, cerebral palsy, schizoaffective disorder, adhd, high functioning autism—so I may as well try to better others because when I’ve done so before, once the illness that caused the psychotic break to come on wasn’t apparent, I did help some people and I honestly felt like true self. Not a miracle worker. Just -J.

Okay after a rebuild I can get a million miles eV

I redesigned the transistor this morning and this is the mathematics I came up with:

Nine Molecule Build.
236,7107kj/mole = 657.52972222222 kWh.
833/5.54=150.36 units to replace.
657.52972222222 kWh x 150.36 = 98866.1690333 kWh
98866.1690333/3600= 27.4628 kW/Second
Assume it’s duty cycle due to heat is 15 seconds on then off to keep it easy: Keeping it at 44 C or less.
15 Seconds x 27.4628 kW/S= 411.942 kW/S
411.942 kW/S 83 unit/kWh = 4.9631 Unit/S
150 units/4.9631 units/second = 30.2230 seconds until full. So since it has to remain dormant for that long as well we double it to roughly 60.4460 seconds. Though if the person loads, waits, then loads again then its 45.2190 seconds and the person behind them has to wait 15 seconds. Time enough to pull away from the station.

Range: Getting to a million miles.
200kWh = 1000 km
98866.1690kWh/200kWhx1000km= 494,330.845km range on fill up.
1,000,000 miles = 1609344 km.
3.2556 x 833kg/1 ton (907.185 kg)=2.9894 tonnes at 150 x 3.2556 units = 488.34 units.
Heavy Cars and Trucks, but everything else will benefit.

How to get a Tesla charge up to 12460 kWh system while getting a range of 62,303.75 KM per charge—all in under two minutes.

My “Batteries” weight roughly 5.54kg or 12lbs meaning you can fit just over 150 units into a 2020 Roadster battery bay and keep the weight ratios the same.

So I’ve figured out how to get this done. I’m hoping people will take it seriously, so I can start working on it properly. I need access to a University so I can sit there and self study with mentor ship as needed for dumb questions I have from the lack of a formal education and what that brings—but yes, this is possible.

You may use batteries if you want, but this system doesn’t. It still allows for regenerative braking in that it slows down immediately after you take your foot off the brake but as long as there’s some charge—which a device within the pedal’s housings could do mechanically (making electrons flow into the system) you would get immediate acceleration due that sheer amount of output the devices create.

I suppose you could say it could do away with the need for batteries all together, though I assume it would be some hybrid type at first while people accept that sort of thing.

The thing is that it creates an immense amount of heat if run for a long time. But as long as there’s things are cycled properly then it can pulse energy into the system from one beginning set of batteries through the system to the opposing battery system if that’s even needed at all and it wouldn’t even feel warm to the user. It would also be usable with a 30 Amp 240 volt system as they like to use now, though I wrote that maths down somewhere on a scrap of paper and can’t seem to find it.

It does mean a change in the design of the car outright from motor driven to production driven, which may scare a few people but once they realize their car goes when they hit the pedal and slows when they hit the brake they’re not going to care either way. And if it takes two minutes to charge the device then it will cost almost nothing to charge them because you would use similar tech to replace the grid or at least update it and they could be subsidized. That much I haven’t thought on long to be honest.

Here’s hoping Elon is listening and his team take this seriously. To get 1,000,000 km
200 kWh = 1,000 km
200,000 kWh = 1,000,000 km
200,000/12460.75= 16.0504 x 150 units = 2,408 units. Weighing in at 2,408x 5.54kg = 13337.8809 kg/ 1 ton = 14.7025 tons, so useful for cargo ships, trucks, but perhaps not retail cars at the moment and retail trucks due unless their low center of gravity could be used to keep them on the road, but the tires would have to be able to handle the weight, let alone the frame. What a massive work.

Anyway, have a good night/morning.